A semiconductor device manufacturing method is obtained which is capable of depositing a ruthenium film with excellent homogeneity in the film quality and excellent reproducibility of the surface morphology. The semiconductor device manufacturing method of the present invention includes heating a silicon wafer up to a temperature of 290-350° C. by means of a heater, supplying an N2 gas to the reaction chamber thereby to hold the pressure in the reaction chamber at a level of 60-4,000 Pa, supplying to the reaction chamber a raw material gas containing ruthenium while decreasing the amount of supply of the N2 gas, thereby to hold the pressure in the reaction chamber at a level of 60-4,000 Pa, supplying to the reaction chamber an oxygen-containing gas containing oxygen after the amount of supply of the raw material gas becomes constant while decreasing the amount of supply of the N2 gas so as to hold the pressure in the reaction chamber at a level of 60-4,000 Pa, decreasing the amount of supply of the oxygen-containing gas after a ruthenium film is deposited, decreasing the amount of supply of the raw material gas so as to stop the supply of the oxygen-containing gas and the supply of the raw material gas, and increasing the amount of supply of the N2 gas thereby to hold the pressure in the reaction chamber at a level of 60-4,000 Pa.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A semiconductor device manufacturing method in which a ruthenium film is formed on a substrate by using a raw material gas containing ruthenium and an oxygen-containing gas containing oxygen, characterized by controlling an oxygen ratio before the start of deposition of said ruthenium film or after the end of deposition thereof to be smaller than an oxygen ratio at the time of deposition thereof.
2. The semiconductor device manufacturing method as set forth in claim 1 , characterized by supplying said raw material gas earlier than said oxygen-containing gas before the start of deposition of said ruthenium film.
3. The semiconductor device manufacturing method as set forth in claim 1 , characterized by gradually increasing the amount of supply of said oxygen-containing gas before the start of deposition when said raw material gas and said oxygen-containing gas are supplied at the same time before the start of deposition of said ruthenium film.
4. The semiconductor device manufacturing method as set forth in claim 1 , characterized by controlling the amount of supply of said oxygen-containing gas before the start of deposition to be smaller than the amount of supply of said oxygen-containing gas at the time of deposition, or controlling the amount of supply of said oxygen-containing gas before the start of deposition to be not greater than a value at which there takes place no deposition reaction, when said oxygen-containing gas is supplied prior to the supply of said raw material gas before the start of deposition of said ruthenium film.
5. The semiconductor device manufacturing method as set forth in claim 1 , characterized by stopping the supply of said oxygen-containing gas earlier than the supply of said raw material gas after the end of deposition of said ruthenium film.
6. The semiconductor device manufacturing method as set forth in claim 1 , characterized by gradually decreasing the amount of supply of said oxygen-containing gas after the end of deposition when the supply of said raw material gas and the supply of said oxygen-containing gas are stopped at the same time after the end of deposition of said ruthenium film.
7. The semiconductor device manufacturing method as set forth in claim 1 , characterized by controlling the amount of supply of said oxygen-containing gas after the end of deposition to be smaller than the amount of supply of said oxygen-containing gas at the time of deposition, or controlling the amount of supply of said oxygen-containing gas after the end of deposition to be not greater than a value at which there takes place no deposition reaction, when the supply of said raw material gas is stopped earlier than the supply of said oxygen-containing gas after the end of deposition of said ruthenium film.
8. The semiconductor device manufacturing method as set forth in claim 1 , characterized by introducing a gas, which does not contribute to deposition reactions, before the start of deposition of said ruthenium film or after the end of deposition thereof, and holding substantially constant the pressures before the start of deposition, at the time of deposition and after the end of deposition.
9. The semiconductor device manufacturing method as set forth in claim 1 , characterized in that said raw material gas containing ruthenium comprises a gas evaporated from Ru(C 2 H 5 C 5 H 4 ) 2 , and that said oxygen-containing gas containing oxygen comprises an O 2 gas.
10. A semiconductor device manufacturing method in which a ruthenium film is formed on a substrate by using a raw material gas containing ruthenium and an oxygen-containing gas containing oxygen, characterized by controlling an oxygenratio before the start of deposition of said ruthenium film or after the end of deposition thereof to be not greater than a value at which there takes place no deposition reaction.
11. The semiconductor device manufacturing method as set forth in claim 10 , characterized by supplying said raw material gas earlier than said oxygen-containing gas before the start of deposition of said ruthenium film.
12. The semiconductor device manufacturing method as set forth in claim 10 , characterized by gradually increasing the amount of supply of said oxygen-containing gas before the start of deposition when said raw material gas and said oxygen-containing gas are supplied at the same time before the start of deposition of said ruthenium film.
13. The semiconductor device manufacturing method as set forth in claim 10 , characterized by controlling the amount of supply of said oxygen-containing gas before the start of deposition to be smaller than the amount of supply of said oxygen-containing gas at the time of deposition, or controlling the amount of supply of said oxygen-containing gas before the start of deposition to be not greater than a value at which there takes place no deposition reaction, when said oxygen-containing gas is supplied prior to the supply of said raw material gas before the start of deposition of said ruthenium film.
14. The semiconductor device manufacturing method as set forth in claim 10 , characterized by stopping the supply of said oxygen-containing gas earlier than the supply of said raw material gas after the end of deposition of said ruthenium film.
15. The semiconductor device manufacturing method as set forth in claim 10 , characterized by gradually decreasing the amount of supply of said oxygen-containing gas after the end of deposition when the supply of said raw material gas and the supply of said oxygen-containing gas are stopped at the same time after the end of deposition of said ruthenium film.
16. The semiconductor device manufacturing method as set forth in claim 10 , characterized by controlling the amount of supply of said oxygen-containing gas after the end of deposition to be smaller than the amount of supply of said oxygen-containing gas at the time of deposition, or controlling the amount of supply of said oxygen-containing gas after the end of deposition to be not greater than a value at which there takes place no deposition reaction, when the supply of said raw material gas is stopped earlier than the supply of said oxygen-containing gas after the end of deposition of said ruthenium film.
17. The semiconductor device manufacturing method as set forth in claim 10 , characterized by introducing a gas, which does not contribute to deposition reactions, before the start of deposition of said ruthenium film or after the end of deposition thereof so as to hold substantially constant the pressures before the start of deposition, at the time of deposition and after the end of deposition.
18. The semiconductor device manufacturing method as set forth in claim 10 , characterized in that said raw material gas containing ruthenium comprises a gas evaporated from Ru(C 2 H 5 C 5 H 4 ) 2 , and that said oxygen-containing gas containing oxygen comprises an O 2 gas.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
September 27, 2001
October 8, 2002
Browse 5M+ US patents with plain-English claim translations and AI-generated analysis.